Probe Modules for Wafer-Level Testing of Gigascale Chips with Electrical and Optical I/O Interconnects

The use of optical input/output (I/O) interconnects, in addition to electrical I/Os, is a promising approach for achieving high-bandwidth, chip-to-board communications required for future high-performance gigascale chip-based systems. While numerous efforts are underway to investigate the integration of optoelectronics and silicon microelectronics, virtually no work has been reported relating to testing of such chips. The objective of this research is to explore methods that enable wafer-level testing of gigascale chips having electrical and optical I/O interconnects. A major challenge in achieving this is to develop probe modules which would allow high-precision, temporary interconnection of a multitude of electrical and optical I/Os, in a chip-size area, to automated test equipment. A probe module would need to do this in a rapid, step-and-repeat manner across all the chips on the wafer. In this work, two candidate probe modules were devised, batch-fabricated on Si using microfabrication techniques, and successfully demonstrated. The first probe module consists of compliant electrical probes (10^3 probes/cm^2) fabricated alongside grating-in-waveguide optical probes. The second module consists of micro-opto-electro-mechanical-systems (MOEMS)-based microsocket probes (10^4 probes/cm^2) to interface a chip with polymer pillar-based electrical and optical I/Os. High-density through-wafer interconnects are an essential attribute in both probe substrates for transferring electrical and optical signals to the substrate back-side. Fabrication and characterization of metal-clad, metal-filled, and polymer-filled through-wafer interconnects as well as process integration with probe substrate fabrication are described and numerous possible redistribution schemes are explicated. Chips with optical and electrical I/Os are an emerging technology, and one that test engineers are likely to encounter in the near future. The contributions of this thesis are to help understand and address the issues relating to joint electrical and optical testing during manufacturing.Ph.D.Committee Chair: Meindl, James; Committee Member: Callen, William; Committee Member: Gaylord, Thomas; Committee Member: Hess, Dennis; Committee Member: May, Gar

IPACK2005-73302 PROBE MODULE FOR WAFER-LEVEL TESTING OF GIGASCALE CHIPS WITH ELECTRICAL AND OPTICAL I/O INTERCONNECTS

ABSTRACT The bandwidth provided by optical interconnects makes them an attractive solution for chip-to-package and chip-to-chip communications. In such systems, chips will have optical I/O interconnects fabricated alongside their conventional electrical counterparts. Virtually no work has been previously reported relating to the testing of such chips at the wafer-level. The requirements for probe hardware needed to achieve this are identified, and probe module configurations based on these requirements are presented. A high-density micro-opto-electro-mechanicalsystems(MOEMS)-based probe substrate prototype for interfacing with chips having electrical and optical polymer pillar-base

Strong Electro-Absorption in GeSi Epitaxy on Silicon-on-Insulator (SOI)

We have investigated the selective epitaxial growth of GeSi bulk material on silicon-on-insulator substrates by reduced pressure chemical vapor deposition. We employed AFM, SIMS, and Hall measurements, to characterize the GeSi heteroepitaxy quality. Optimal growth conditions have been identified to achieve low defect density, low RMS roughness with high selectivity and precise control of silicon content. Fabricated vertical p-i-n diodes exhibit very low dark current density of 5 mA/cm2 at −1 V bias. Under a 7.5 V/µm E-field, GeSi alloys with 0.6% Si content demonstrate very strong electro-absorption with an estimated effective ∆α/α around 3.5 at 1,590 nm. We compared measured ∆α/α performance to that of bulk Ge. Optical modulation up to 40 GHz is observed in waveguide devices while small signal analysis indicates bandwidth is limited by device parasitics

Strong Electro-Absorption in GeSi Epitaxy on Silicon-on-Insulator (SOI)

We have investigated the selective epitaxial growth of GeSi bulk material on silicon-on-insulator substrates by reduced pressure chemical vapor deposition. We employed AFM, SIMS, and Hall measurements, to characterize the GeSi heteroepitaxy quality. Optimal growth conditions have been identified to achieve low defect density, low RMS roughness with high selectivity and precise control of silicon content. Fabricated vertical <em>p</em>-<em>i</em>-<em>n</em> diodes exhibit very low dark current density of 5 mA/cm<sup>2</sup> at −1 V bias. Under a 7.5 V/µm E-field, GeSi alloys with 0.6% Si content demonstrate very strong electro-absorption with an estimated effective ∆α/α around 3.5 at 1,590 nm. We compared measured ∆α/α performance to that of bulk Ge. Optical modulation up to 40 GHz is observed in waveguide devices while small signal analysis indicates bandwidth is limited by device parasitics